#' Plot feature contribution as a bar graph
#' 
#' Plot previously calculated feature contribution as a bar graph.
#' 
#' @param tree_interpretation_dt a \code{data.table} returned by \code{\link{lgb.interprete}}.
#' @param top_n maximal number of top features to include into the plot.
#' @param cols the column numbers of layout, will be used only for multiclass classification feature contribution.
#' @param left_margin (base R barplot) allows to adjust the left margin size to fit feature names.
#' @param cex (base R barplot) passed as \code{cex.names} parameter to \code{barplot}.
#' 
#' @details
#' The graph represents each feature as a horizontal bar of length proportional to the defined contribution of a feature.
#' Features are shown ranked in a decreasing contribution order.
#' 
#' @return
#' The \code{lgb.plot.interpretation} function creates a \code{barplot}.
#' 
#' @examples
#' \dontrun{
#' library(lightgbm)
#' Sigmoid <- function(x) {1 / (1 + exp(-x))}
#' Logit <- function(x) {log(x / (1 - x))}
#' data(agaricus.train, package = "lightgbm")
#' train <- agaricus.train
#' dtrain <- lgb.Dataset(train$data, label = train$label)
#' setinfo(dtrain, "init_score", rep(Logit(mean(train$label)), length(train$label)))
#' data(agaricus.test, package = "lightgbm")
#' test <- agaricus.test
#' 
#' params = list(objective = "binary",
#'               learning_rate = 0.01, num_leaves = 63, max_depth = -1,
#'               min_data_in_leaf = 1, min_sum_hessian_in_leaf = 1)
#'               model <- lgb.train(params, dtrain, 20)
#' model <- lgb.train(params, dtrain, 20)
#' 
#' tree_interpretation <- lgb.interprete(model, test$data, 1:5)
#' lgb.plot.interpretation(tree_interpretation[[1]], top_n = 10)
#' }
#' @importFrom graphics barplot par
#' @export
lgb.plot.interpretation <- function(tree_interpretation_dt,
                                    top_n = 10,
                                    cols = 1,
                                    left_margin = 10,
                                    cex = NULL) {
  
  # Get number of columns
  num_class <- ncol(tree_interpretation_dt) - 1
  
  # Refresh plot
  op <- graphics::par(no.readonly = TRUE)
  on.exit(graphics::par(op))
  
  # Do some magic plotting
  graphics::par(mar = op$mar %>% magrittr::inset(., 1:3, c(3, left_margin, 2)))
  
  # Check for number of classes
  if (num_class == 1) {
    
    # Only one class, plot straight away
    multiple.tree.plot.interpretation(tree_interpretation_dt,
                                      top_n = top_n,
                                      title = NULL,
                                      cex = cex)
    
  } else {
    
    # More than one class, shape data first
    layout_mat <- matrix(seq.int(to = cols * ceiling(num_class / cols)),
                         ncol = cols, nrow = ceiling(num_class / cols))
    
    # Shape output
    graphics::par(mfcol = c(nrow(layout_mat), ncol(layout_mat)))
    
    # Loop throughout all classes
    for (i in seq_len(num_class)) {
      
      # Prepare interpretation, perform T, get the names, and plot straight away
      tree_interpretation_dt[, c(1, i + 1), with = FALSE] %T>%
        data.table::setnames(., old = names(.), new = c("Feature", "Contribution")) %>%
        multiple.tree.plot.interpretation(., # Self
                                          top_n = top_n,
                                          title = paste("Class", i - 1),
                                          cex = cex)
      
    }
  }
}

multiple.tree.plot.interpretation <- function(tree_interpretation,
                                              top_n,
                                              title,
                                              cex) {
  
  # Parse tree
  tree_interpretation <- tree_interpretation[order(abs(Contribution), decreasing = TRUE),][seq_len(min(top_n, .N)),]
  
  # Attempt to setup a correct cex
  if (is.null(cex)) {
    cex <- 2.5 / log2(1 + top_n)
  }
  
  # Do plot
  tree_interpretation[.N:1,
                      graphics::barplot(
                          height = Contribution,
                          names.arg = Feature,
                          horiz = TRUE,
                          col = ifelse(Contribution > 0, "firebrick", "steelblue"),
                          border = NA,
                          main = title,
                          cex.names = cex,
                          las = 1
                      )]
  
  # Return invisibly
  invisible(NULL)
  
}
